Intelligent collaborative active heat dissipation one-two fusion complete ring network box
By using the rotatable linkage design of the connecting plate and the receiving plate and the coordinated heat dissipation structure of the protective shell, the problem of needing to lay a separate cement base for the matching meter box is solved, thereby improving construction efficiency and saving costs, while ensuring the stable operation of the equipment in complex outdoor environments.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- ZHEJIANG BRWOR ELECTRIC CO LTD
- Filing Date
- 2026-03-30
- Publication Date
- 2026-06-26
AI Technical Summary
In existing technologies, the matching meter box requires a separate cement base, which leads to complicated construction procedures, increased time consumption, high material and labor costs, and waste of resources.
A smart, collaborative, and active heat dissipation integrated primary and secondary ring network box was designed. Through the rotatable linkage structure of the connecting plate and the receiving plate, the receiving plate can horizontally support the metering box in a supported state, eliminating the need for separate planning of installation location and laying of a special cement base. Combined with the protective shell and exhaust fan, collaborative heat dissipation is achieved, reducing transportation costs.
It reduces construction steps, saves on base construction materials and labor costs, improves heat dissipation efficiency, reduces transportation costs, and is suitable for factory transportation scenarios.
Smart Images

Figure CN122292157A_ABST
Abstract
Description
Technical Field
[0001] This application relates to the technical field of smart grids, and in particular to a fully integrated primary and secondary ring network box with intelligent collaborative active heat dissipation. Background Technology
[0002] In the process of smart grid construction and upgrading, integrated primary and secondary ring main units (RMUs) serve as core equipment in power distribution networks. Leveraging their integrated and intelligent technological advantages, they are widely used in outdoor power distribution scenarios, playing a crucial role in power distribution, line protection, and ring network power supply. The ease of installation and compatibility of these RMUs directly impact the construction efficiency and overall cost of power distribution projects. To adapt to the complex outdoor environment, these RMUs have established standardized technical systems in structural design and installation processes, becoming an important foundation for the construction of outdoor power distribution systems.
[0003] In existing technology, outdoor integrated primary and secondary ring mainframe boxes mainly consist of a box body and a door rotatably connected to the front of the box body. Ventilation vents are provided on the left and right sides of the box body to ensure heat dissipation during equipment operation. The standardized installation process for this ring mainframe box is as follows: before construction, a cement base is laid at the designated outdoor installation location. After the base has cured to the required standard, the bottom surface of the ring mainframe box is fixed to the upper surface of the cement base with screws, thus achieving stable installation of the ring mainframe box. This process is widely used in the industry.
[0004] In practical power distribution engineering applications, ground-mounted meter boxes are usually installed near ring main units to enable the connection of electricity metering and branch power distribution functions. However, in existing technologies, the installation of ground-mounted meter boxes must follow the same process requirements as ring main units, requiring separate planning of installation locations and the laying of special cement bases. This not only leads to cumbersome construction procedures and a significant increase in on-site operation time, but also consumes additional material and labor costs for base construction, resulting in resource waste and room for improvement. Summary of the Invention
[0005] The purpose of this application is to provide an intelligent collaborative active heat dissipation integrated primary and secondary ring network box, which solves the problem in the above-mentioned related technologies that the matching meter box needs to be laid on a separate cement base, resulting in complicated construction procedures, increased time consumption, high material and labor costs, and waste of resources.
[0006] The intelligent collaborative active heat dissipation integrated primary and secondary ring network box provided in this application adopts the following technical solution: A fully integrated ring network box for intelligent collaborative active heat dissipation, comprising a box body and a door rotatably mounted on the front side of the box body, with heat dissipation vents on the left and right sides of the box body; a connecting plate is rotatably connected to a vertical surface on one side of the box body, the connecting plate being able to rotate to a vertically downward supporting state and to a horizontally outward storage state, with a receiving plate vertically fixed on the side of the connecting plate away from the box body; when the connecting plate is in the supporting state, the receiving plate rotates to a horizontally outward receiving state, at which point the top surface of the receiving plate can be used for the installation and fixing of a metering box; when the connecting plate is in the storage state, the receiving plate is in a vertically upward transport state and fixed.
[0007] By adopting the above technical solution, the rotatable linkage design of the connecting plate and the receiving plate allows the receiving plate to horizontally support the metering box in a supported state. This eliminates the need for separate planning of installation locations and laying of dedicated cement bases for the metering box, reducing construction procedures, shortening on-site operation time, and saving material and labor costs required for base construction, thus avoiding resource waste. During transportation, both can be switched to a stowed state, reducing the overall volume of the ring network box, lowering packaging and transportation costs, and adapting to factory transportation scenarios.
[0008] Optionally, when the receiving plate is in the receiving state, it is located below the heat dissipation vent. At this time, the upper side of the connecting plate has a clearance notch. A protective shell is detachably installed on the top edge of the receiving plate, with one side snapping into the clearance notch and abutting against the outer side of the box. The protective shell has protective openings on both the side facing and away from the heat dissipation vent. The front and rear sides of the protective shell have installation notches, and an exhaust fan is fixed in the installation notch. When the metering box is installed on the top surface of the receiving plate, the edges of the two protective openings cover the heat dissipation vents on the sides of the metering box and the ring network box that are close to each other. The exhaust fan is used to drive the air circulation inside the metering box and the ring network box.
[0009] By adopting the above technical solution, the protective shell can be detachably installed and fits snugly against the enclosure and the supporting plate, providing protection for the heat dissipation vents and preventing outdoor debris from entering and affecting equipment operation. The protective opening precisely aligns with the heat dissipation vents of the two devices, and together with the exhaust fan, it can simultaneously drive the air circulation inside both devices, significantly improving heat dissipation efficiency and ensuring stable operation of the equipment in complex outdoor environments.
[0010] Optionally, the protective shell is vertically upward when the receiving plate is in the transport and receiving state. When the receiving plate is in the receiving state, the bottom edge of the protective shell away from the box is rotatably connected to the top surface of the receiving plate. When the receiving plate is in the transport state, the side of the protective shell away from the box abuts against the side of the receiving plate facing the box.
[0011] By adopting the above technical solution, the protective shell always remains vertically upward, adapting to both the receiving and transportation of the receiving plate. The state switching can be completed without disassembly, improving ease of use. In the receiving state, its rotating connection facilitates precise alignment with the heat dissipation vents of the two devices, ensuring coordinated heat dissipation. In the transportation state, the protective shell fits snugly against the receiving plate and the housing for storage, preventing damage from collisions during transportation. It also does not occupy extra space. Combined with the storage structure of the connecting plate and the receiving plate, the overall volume is further reduced, lowering transportation costs and balancing practicality and economy.
[0012] Optionally, the connecting plate is provided with an elastic limiting rod, one end of which is rotatably connected to the outer side of the housing and has elastic elongation properties. The rotation surface of the elastic limiting rod is parallel to the side of the housing facing the connecting plate. First slots are provided on the front and rear sides of the protective shell, and a second slot is provided on the top surface of the connecting plate when it is in the supporting state. When the receiving plate is in the transport state, the elastic limiting rod can rotate to a horizontal limiting state along the direction of the downward protective shell, and the end of the elastic limiting rod is inserted into the first slot at this time. When the receiving plate is in the receiving state, the elastic limiting rod rotates to a vertically downward positioning state, and the lower end of the elastic limiting rod is inserted into the second slot at this time.
[0013] By adopting the above technical solution, the elastic limiting rod possesses elastic elongation performance, allowing for convenient rotation and secure locking. During transport, it engages with the first slot to lock the protective shell, preventing damage from shaking; in the receiving state, it engages with the second slot to fix the connecting plate, preventing rotational deviation and ensuring stable installation of the metering box. Its rotating surface is compatible with the box body, featuring a compact structural design that eliminates the need for additional limiting components, does not increase equipment size, and balances positioning reliability with ease of use, further optimizing the overall adaptability of equipment transportation and installation.
[0014] Optionally, when the receiving plate is in the receiving state, a fixed notch is provided on the side edge away from the box body. A middle rod is rotatably connected to the inner wall of the fixed notch away from the connecting plate. An adjustable support rod is vertically fixed to the other end of the middle rod. A control component is provided on the receiving plate. When the receiving plate is in the transport state, the support rod rotates with the middle rod to a vertically downward and stored state between the box body and the receiving plate. At this time, the middle rod is in a horizontal direction and disengages from the fixed notch. When the receiving plate is in the receiving state, the support rod can rotate with the middle rod to a vertically downward supporting state. At this time, the middle rod is in a horizontal direction and rotates into the fixed notch. The control component is used to limit the movement of the middle rod in this state.
[0015] By adopting the above technical solution, in the receiving state, the intermediate rod is turned into the fixed notch, the support rod is vertically downward and its length is adjusted to touch the ground, which can effectively distribute the load of the metering box and prevent the receiving plate from shifting. With the help of the control components, the support is stable. In the transportation state, the support rod and the intermediate rod are stored between the box and the receiving plate, without occupying extra space or increasing the size of the equipment.
[0016] Optionally, the elastic limiting rod has a protrusion on its top surface when it is inserted into the first slot, and the protrusion has a limiting notch on its top surface at this time; the support rod is rotatably connected to the intermediate rod, the rotation surface of the support rod is parallel to the end face of the intermediate rod away from the receiving plate, and the lower end of the support rod in the retracted state can be inserted into the limiting notch.
[0017] By adopting the above technical solution, the support rod and the elastic limiting rod in their stowed state can be locked together to prevent them from shaking or shifting during transportation. The rotational adaptation design of the support rod and the intermediate rod facilitates precise engagement with the limiting notch, making operation convenient and eliminating the need for additional locking components. This structure makes full use of existing elastic limiting rods and support rods, with a compact design that does not occupy extra space, further improving the integrity and stability of each component during transportation, reducing the risk of collision damage, and balancing convenience and reliability.
[0018] Optionally, the control component includes a control plate slidably mounted on the side of the receiving plate facing the connecting plate. The control plate is capable of reciprocating along the direction towards the connecting plate. Two control protrusions are detachably mounted on the side of the control plate facing the connecting plate. An extension block is fixed on the top surface of the intermediate rod when the support rod is in the supported state. A control slot is opened on the side of the extension block away from the connecting plate at this time. The control protrusion slides with the control plate and is embedded in the control slot.
[0019] By adopting the above technical solution, the control plate slides smoothly, and the control protrusions slide along it to precisely embed into the control slots of the extension block, quickly locking the intermediate rod and support rod to prevent them from rotating or shifting under force, ensuring stable support for the receiving plate and guaranteeing the secure installation of the metering box. The detachable design of the control protrusions facilitates maintenance and replacement. The overall structure fits the existing design of the receiving plate and intermediate rod, is compact and does not occupy extra space, is easy to operate and has reliable limiting, further optimizing the structural stability and practicality of the equipment installation.
[0020] Optionally, two fixing slots are provided on the top surface of the protective shell, and the two control protrusions are slidably connected to the control plate. The control protrusions can slide and adjust along the length of the control plate. When the receiving plate is in the transport state, the control plate can slide downwards, and the control protrusions can simultaneously slide downwards and embed into the fixing slots.
[0021] By adopting the above technical solution, the control protrusion can slide and adjust along the control plate to fit the fixed slot position. During transportation, the control plate moves downward, causing the control protrusion to embed into the fixed slot, thus doubly locking the protective shell. This design reuses existing control components, eliminating the need for additional locking structures. It is compact, space-saving, and easy to operate. It not only enhances the fixing effect of the protective shell during transportation, preventing damage from shaking, but also takes into account the multifunctionality of the control components, improving the integration and reliability of the overall equipment structure, and adapting to the usage requirements of transportation scenarios.
[0022] Optionally, an elastic snap-fit element is provided on the outer surface of the control protrusion, and positioning grooves for the elastic snap-fit element to be snapped into are provided on the inner walls of both the control slot and the fixing slot.
[0023] By adopting the above technical solution, the elastic snap-fit component adapts to the positioning groove, allowing the control protrusion to be firmly locked into the slot, preventing loosening or displacement during equipment operation or transportation. The structure is simple, requires no additional operation, does not increase the equipment size, and simultaneously enhances the limiting reliability of the control components in both installation and transportation states, ensuring the overall structural stability of the equipment.
[0024] Optionally, the elastic snap-fit component includes a compression spring and an arc-shaped protrusion. The outer side of the control protrusion is provided with a placement groove for the compression spring and the arc-shaped protrusion to be placed. The compression spring squeezes one side of the arc-shaped protrusion, causing a part of the arc-shaped protrusion to protrude from the opening of the placement groove. The outer side of the protruding part of the arc-shaped protrusion is an arc surface, and the arc length corresponding to this arc surface is a minor arc.
[0025] By adopting the above technical solution, the compression spring presses against the arc-shaped protrusion to achieve stable engagement. The slightly concave arc surface design facilitates the smooth insertion or removal of the protrusion from the slot without additional force. The structural design is simple, adaptable to existing placement slots, does not increase the size of the equipment, and at the same time improves the durability of the elastic engagement component, further enhancing the limiting stability of the control protrusion.
[0026] In summary, this application includes the following beneficial technical effects: In this application, the rotatable linkage design of the connecting plate and the receiving plate allows the receiving plate to horizontally support the metering box in a supported state. This eliminates the need for separate planning of installation locations and laying of dedicated cement bases for the metering box, reducing construction procedures, shortening on-site operation time, and saving material and labor costs required for base construction, thus avoiding resource waste. During transportation, both can be switched to a stowed state, reducing the overall volume of the ring network box, lowering packaging and transportation costs, and adapting to factory transportation scenarios. Attached Figure Description
[0027] Figure 1 This is a schematic diagram of the overall structure of Embodiment 1 of this application; Figure 2 This is a partial structural diagram illustrating the installation and assembly of the receiving components in an embodiment of this application; Figure 3 This is a partial structural diagram illustrating the installation and cooperation of the receiving plate and the connecting plate in an embodiment of this application; Figure 4 This is an exploded structural diagram illustrating the installation and distribution of the protective shell and the supporting plate in an embodiment of this application; Figure 5 This is a partial cross-sectional view of the installation and fit of the elastic limiting rod in an embodiment of this application; Figure 6 This is a partial structural diagram illustrating the installation and fit of the support components in an embodiment of this application; Figure 7 This is a partial structural diagram illustrating the installation and assembly of the control components in an embodiment of this application; Figure 8 This is an exploded structural diagram illustrating the installation distribution of control components and support components according to an embodiment of this application; Figure 9 This is an exploded structural diagram illustrating the installation and distribution of the control components and the receiving plate in an embodiment of this application; Figure 10 This is a partial cross-sectional view of the structure of the control board and control bumps in an embodiment of this application. Figure 11 This is a partial cross-sectional view of an embodiment of the present application illustrating the installation and cooperation of the extension block and the control protrusion; Figure 12 yes Figure 11 An enlarged schematic diagram of part A in the middle.
[0028] In the diagram, 1. Box body; 11. Heat dissipation vent; 12. Elastic limiting rod; 13. Protrusion; 131. Limiting notch; 2. Box door; 3. Supporting component; 31. Connecting plate; 311. Clearance notch; 312. Second slot; 32. Supporting plate; 321. Fixing notch; 4. Protective component; 41. Protective shell; 411. Protective opening; 412. Installation notch; 413. First slot; 414. Fixing slot; 42. Exhaust fan; 5. Support component; 51. Intermediate rod; 52. Support rod; 53. Extension block; 531. Control slot; 532. Positioning groove; 6. Control component; 61. Control plate; 62. Control protrusion; 621. Placement slot; 63. Elastic snap-fit component; 631. Compression spring; 632. Arc-shaped protrusion. Detailed Implementation
[0029] The present application will be further described in detail below with reference to all the accompanying drawings. Example
[0030] Reference Figure 1 , Figure 2 and Figure 3 A smart collaborative active heat dissipation integrated primary and secondary ring mesh box includes a box body 1 and a box door 2 rotatably installed on the front side of the box body 1. Heat dissipation vents 11 are provided on the left and right sides of the box body 1. A supporting component 3 is provided on the vertical surface of one side of the box body 1. The supporting component 3 includes a connecting plate 31 rotatably connected to the vertical outer side of the box body 1 on one side. The connecting plate 31 can be rotated to a vertically downward supporting state and to a horizontally outward storage state. A supporting plate 32 is vertically fixed on the side of the connecting plate 31 away from the box body 1. When the ring network box is installed and applied, the connecting plate 31 is in a supporting state, and the receiving plate 32 is simultaneously rotated to a horizontal outward receiving state. At this time, the top surface of the receiving plate 32 can be used to install and fix the metering box. When the ring network box is shipped out of the factory, the connecting plate 31 is in a storage state, and the receiving plate 32 is simultaneously rotated to a vertical upward transportation state and fixed, reducing the overall volume and reducing packaging and transportation costs.
[0031] Reference Figure 3 and Figure 4 When the receiving plate 32 is in the receiving state, it is located below the heat dissipation vent 11. The upper side of the connecting plate 31 is provided with a clearance notch 311. The top surface of the receiving plate 32 is provided with a protective component 4. The protective component 4 includes a protective shell 41 that can be detachably installed on the top surface of the receiving plate 32. One side of the protective plate is inserted into the clearance notch 311 and abuts against the outer side of the box 1. The protective shell 41 has protective openings 411 on the sides facing and away from the heat dissipation vent 11. The front and rear sides of the protective shell 41 have mounting notches 412 and an exhaust fan 42 fixed in the mounting notch 412. The exhaust fan 42 has a small motor and is a conventional heat dissipation and exhaust structure, which will not be described in detail here. When a metering box is installed on the top surface of the receiving plate 32, the edges of the two protective openings 411 are respectively covered on the outside of the heat dissipation openings 11 on the sides of the metering box and the ring network box that are close to each other. The exhaust fan 42 can simultaneously drive the air circulation inside the metering box and the ring network box, thereby improving the corresponding heat dissipation performance.
[0032] Reference Figure 2 and Figure 3 The protective shell 41 is vertically upward when the receiving plate 32 is in the transport and receiving state. When the receiving plate 32 is in the receiving state, the bottom edge of the protective shell 41 away from the box 1 is rotatably connected to the top surface of the receiving plate 32. When the receiving plate 32 is in the transport state, the side of the protective shell 41 away from the box 1 abuts against the side of the receiving plate 32 facing the box 1, and the side facing the box 1 abuts against the vertical outer side of the box 1. In this state, the protective shell 41 is housed between the receiving plate 32 and the box 1, reducing the possibility of damage to the protective shell 41 during transportation.
[0033] Reference Figure 3 , Figure 4 and Figure 5 The connecting plate 31 is provided with an elastic limiting rod 12 at one end that is rotatably connected to the outer side of the box 1. The rotating surface of the elastic limiting rod 12 is parallel to the side of the box 1 facing the connecting plate 31. The elastic limiting rod 12 is a conventional telescopic structure with an internal spring and elastic elongation performance, which will not be described in detail here. The protective shell 41 is provided with a first slot 413 on both the front and rear sides, and a second slot 312 is provided on the top surface of the connecting plate 31 when it is in the supported state. When the receiving plate 32 is in the transport state, the elastic limiting rod 12 can rotate to a horizontal limiting state in the direction toward the protective shell 41, and the end of the elastic limiting rod 12 is inserted into the first slot 413 at this time; when the receiving plate 32 is in the receiving state, the elastic limiting rod 12 rotates to a vertically downward positioning state, and the lower end of the elastic limiting rod 12 is inserted into the second slot 312 at this time.
[0034] Reference Figure 4 , Figure 6 and Figure 7 The receiving plate 32 is provided with a control component 6. When the receiving plate 32 is in the receiving state, a fixing notch 321 is opened on the side edge away from the box 1, and a support component 5 is provided inside the intermediate rod 51. The support component 5 includes an intermediate rod 51 with one end rotatably connected to the inner wall of the connecting plate 31 away from the fixing notch 321. The other end of the intermediate rod 51 is vertically fixed with a support rod 52 whose length is adjustable and fixed by screws. The support rod 52 is a conventional telescopic structure, which will not be described in detail here. When the receiving plate 32 is in the transport state, the support rod 52 rotates with the middle rod 51 to the storage state of being vertically downward and located between the box 1 and the receiving plate 32. At this time, the middle rod 51 is in the horizontal direction and comes out from the fixing notch 321. At this time, the two support rods 52 are located on the front and rear sides of the protective shell 41, respectively. When the receiving plate 32 is in the receiving state, the support rod 52 can rotate with the intermediate rod 51 to a vertically downward supporting state. At this time, the intermediate rod 51 is in the horizontal direction and rotates into the fixed notch 321. The control component 6 is used to limit the intermediate rod 51 in this state. At this time, the length of the support rod 52 can be adjusted and fixed so that the lower end of the support rod 52 is in contact with the ground. In this way, the combined structure of the support rod 52 and the intermediate rod 51 can be used to provide auxiliary support for the receiving plate 32 in this state.
[0035] Reference Figure 6 The elastic limiting rod 12 has a protrusion 13 fixed on its top surface when it is inserted into the first slot 413. The protrusion 13 has a limiting notch 131 on its top surface at this time. The support rod 52 is rotatably connected to the intermediate rod 51. The rotating surface of the support rod 52 is parallel to the end face of the intermediate rod 51 away from the receiving plate 32. When the receiving plate 32 is in the transport state, the support rod 52 is in the storage state. At this time, the length of the support rod 52 can be adjusted, and then the support rod 52 can be rotated so that the lower end of the support rod 52 can be inserted into the limiting notch 131, thereby enhancing the installation stability of the elastic limiting rod 12 in this state.
[0036] Reference Figure 7 and Figure 8The control component 6 includes a control plate 61 (using a dovetail slider and a dovetail groove) that is slidably mounted on the side of the receiving plate 32 facing the connecting plate 31. The control plate 61 can slide back and forth in the direction facing the connecting plate 31. Two control protrusions 62 are detachably mounted on the side of the control plate 61 facing the connecting plate 31. An extension block 53 is fixed on the top surface of the intermediate rod 51 when the support rod 52 is in the supported state. The extension block 53 has a control slot 531 on the side away from the connecting plate 31. When the support rod 52 is in the supported state, the control plate 61 is located on the side of the extension block 53 away from the extension plate, and the control protrusion 62 slides with the control plate 61 and is embedded in the control slot 531.
[0037] Reference Figure 8 , Figure 9 and Figure 10 Two fixing slots 414 are provided on the top surface of the protective shell 41. Two control protrusions 62 are slidably connected to the control plate 61 (achieved through the cooperation of dovetail slider and dovetail groove). The control protrusions 62 can slide and adjust along the length direction of the control plate 61. When the receiving plate 32 is in the transport state, the control plate 61 can slide down, and then the two control protrusions 62 can slide and adjust to be directly above the fixing slot 414. Finally, the control protrusions 62 can move down and embed into the fixing slot 414 in a synchronized manner, so as to further lock and limit the protective shell 41 in this state.
[0038] Reference Figure 10 , Figure 11 and Figure 12 An elastic snap-fit member 63 is provided on the outer side of the control protrusion 62, and a positioning groove 532 is provided on the inner wall of both the control slot 531 and the fixing slot 414. When the control protrusion 62 is inserted into the control slot 531 or the fixing slot 414, the elastic snap-fit member 63 can snap into the corresponding positioning groove 532, thereby enhancing the installation stability of the control protrusion 62 in the corresponding state. The elastic snap-fit component 63 includes a compression spring 631 and an arc-shaped protrusion 632. A placement groove 621 is provided on the outer side of the control protrusion 62 for the compression spring 631 and the arc-shaped protrusion 632 to be placed. The compression spring 631 squeezes one side of the arc-shaped protrusion 632, causing a part of the arc-shaped protrusion 632 to protrude from the opening of the placement groove 621. The outer side of the protruding part of the arc-shaped protrusion 632 is an arc surface, and the arc length corresponding to this arc surface is a minor arc.
[0039] The implementation principle of this application embodiment is as follows: During transport, the connecting plate 31 is rotated to a horizontal storage position, the receiving plate 32 is simultaneously vertically upward, and the protective shell 41 is vertically upward and stored between the receiving plate 32 and the housing 1. The support rod 52 rotates with the intermediate rod 51 to be stored between the two. The elastic limiting rod 12 rotates to a horizontal position, and its end is inserted into the first slot 413 on the protective shell 41; the lower end face of the support rod 52 is inserted into the limiting notch 131 on the protrusion 13 for limitation; the control plate 61 moves down and the distance between the two control protrusions 62 is adjusted so that the control protrusions 62 move down simultaneously and are embedded into the fixing slot 414 on the protective shell 41; this achieves multi-component locking, reduces the overall volume, and lowers transportation costs.
[0040] In the installation state, the connecting plate 31 rotates to a vertical support state, and the receiving plate 32 is in a receiving state to support the metering box. The elastic limiting rod 12 rotates to a vertical orientation state, and its lower end is inserted into the second slot 312 to position the connecting plate 31; the intermediate rod 51 rotates into the fixing notch 321, and the support rod 52 is lengthened and rotated to a vertical downward state to abut against the ground to provide auxiliary support for the receiving plate 32; the control protrusion 62 is embedded in the control slot 531 on the extension block 53 to lock the state of the intermediate rod 51. The protective shell 41 covers the outside of the heat dissipation vents 11 of the two devices, and the exhaust fan 42 drives the internal air circulation of both devices to achieve coordinated active heat dissipation.
[0041] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be included within the scope of protection of this application.
Claims
1. A fully integrated ring network box for intelligent collaborative active heat dissipation, comprising a box body (1), a box door (2) rotatably mounted on the front side of the box body (1), and heat dissipation vents (11) on the left and right sides of the box body (1); characterized in that, A connecting plate (31) is rotatably connected to one side of the box (1). The connecting plate (31) can be rotated to a vertically downward supporting state and to a horizontally outward storage state. A support plate (32) is vertically fixed on the side of the connecting plate (31) away from the box (1). When the connecting plate (31) is in a supporting state, the receiving plate (32) turns to a horizontal outward receiving state, and the top surface of the receiving plate (32) can be used for the metering box to be installed and fixed at this time; when the connecting plate (31) is in a storage state, the receiving plate (32) is in a vertical upward transport state and fixed.
2. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 1, characterized in that, When the receiving plate (32) is in the receiving state, it is located below the heat dissipation port (11). The connecting plate (31) has a clearance notch (311) on its upper side at this time. The receiving plate (32) is detachably installed with a protective shell (41) on one side that fits into the clearance notch (311) and abuts against the outer side of the box (1). The protective shell (41) has protective openings (411) on both the side facing and away from the heat dissipation port (11). The protective shell (41) has an installation notch (412) on its front and rear sides, and an exhaust fan (42) is fixed in the installation notch (412). When the metering box is installed on the top surface of the receiving plate (32), the edges of the two protective openings (411) are respectively covered outside the heat dissipation vents (11) on the sides of the metering box and the ring network box that are close to each other. The exhaust fan (42) is used to drive the gas flow inside the metering box and the ring network box.
3. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 2, characterized in that, The protective shell (41) is vertically upward when the receiving plate (32) is in the transport and receiving state. When the receiving plate (32) is in the receiving state, the bottom edge of the protective shell (41) away from the box (1) is rotatably connected to the top surface of the receiving plate (32). When the receiving plate (32) is in the transport state, the side of the protective shell (41) away from the box (1) abuts against the side of the receiving plate (32) facing the box (1).
4. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 3, characterized in that, The connecting plate (31) is provided with an elastic limiting rod (12) at one end which is rotatably connected to the outer side of the box (1) and has elastic elongation performance. The rotation surface of the elastic limiting rod (12) is parallel to the side of the box (1) facing the connecting plate (31). The protective shell (41) is provided with a first slot (413) on both the front and rear sides. The connecting plate (31) is provided with a second slot (312) on its top surface when it is in the supported state. When the receiving plate (32) is in the transport state, the elastic limiting rod (12) can rotate to a horizontal limiting state along the direction of the downward protective shell (41), and the end of the elastic limiting rod (12) is inserted into the first slot (413) at this time; when the receiving plate (32) is in the receiving state, the elastic limiting rod (12) rotates to a vertically downward positioning state, and the lower end of the elastic limiting rod (12) is inserted into the second slot (312) at this time.
5. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 4, characterized in that, When the receiving plate (32) is in the receiving state, a fixing notch (321) is provided on the side edge away from the box (1). A middle rod (51) is rotatably connected to the inner wall of the fixing notch (321) away from the connecting plate (31). The other end of the middle rod (51) is vertically fixed with a support rod (52) of adjustable length. A control component (6) is provided on the receiving plate (32). When the receiving plate (32) is in the transport state, the support rod (52) rotates with the intermediate rod (51) to a vertically downward and stored state between the box (1) and the receiving plate (32). At this time, the intermediate rod (51) is in the horizontal direction and disengages from the fixed notch (321). When the receiving plate (32) is in the receiving state, the support rod (52) can rotate with the intermediate rod (51) to a vertically downward supporting state. At this time, the intermediate rod (51) is in the horizontal direction and rotates into the fixed notch (321). The control element (6) is used to limit the intermediate rod (51) in this state.
6. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 5, characterized in that, When the elastic limiting rod (12) is inserted into the first slot (413), a protrusion (13) is fixed on its top surface, and a limiting notch (131) is opened on the top surface of the protrusion (13) at this time; The support rod (52) is rotatably connected to the intermediate rod (51). The rotating surface of the support rod (52) is parallel to the end face of the intermediate rod (51) away from the receiving plate (32). When the support rod (52) is in the retracted state, the lower end can be inserted into the limiting notch (131).
7. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 5, characterized in that, The control component (6) includes a control plate (61) slidably disposed on the side of the receiving plate (32) facing the connecting plate (31). The control plate (61) is capable of reciprocating along the direction facing the connecting plate (31). Two control protrusions (62) are detachably installed on the side of the control plate (61) facing the connecting plate (31). The intermediate rod (51) has an extension block (53) fixed on its top surface when the support rod (52) is in a supported state. The extension block (53) has a control slot (531) on its side away from the connecting plate (31). The control protrusion (62) slides with the control plate (61) and is embedded in the control slot (531).
8. The intelligent collaborative active heat dissipation integrated primary and secondary ring network box according to claim 7, characterized in that, The protective shell (41) has two fixed slots (414) on its top surface. The two control protrusions (62) are slidably connected to the control plate (61). The control protrusions (62) can slide and adjust along the length of the control plate (61). When the receiving plate (32) is in the transport state, the control plate (61) can slide downwards, and the control protrusions (62) can simultaneously slide downwards and embed into the fixed slots (414).
9. A fully integrated primary and secondary ring network box for intelligent collaborative active heat dissipation according to claim 8, characterized in that, An elastic snap-fit member (63) is provided on the outer side of the control protrusion (62), and a positioning groove (532) for the elastic snap-fit member (63) to be snapped into is provided on the inner wall of the control slot (531) and the fixing slot (414).
10. A fully integrated primary and secondary ring network box for intelligent collaborative active heat dissipation according to claim 9, characterized in that, The elastic snap-fit component (63) includes a compression spring (631) and an arc-shaped protrusion (632). The outer side of the control protrusion (62) is provided with a placement groove (621) for the compression spring (631) and the arc-shaped protrusion (632) to be placed. The compression spring (631) squeezes one side of the arc-shaped protrusion (632) so that a part of the arc-shaped protrusion (632) protrudes from the opening of the placement groove (621). The outer side of the protruding part of the arc-shaped protrusion (632) is an arc surface, and the arc length corresponding to the arc surface is a minor arc.